Induction of apoptosis in human myeloid leukemia cells by remote exposure of resistive barrier cold plasma.

Cold atmospheric plasma (CAP), an ambient temperature ionized gas, is gaining extensive interest as a promising addition to anti-tumor therapy primarily due to the ability to generate and control delivery of electrons, ions, excited molecules, UV photons, and reactive species such as reactive oxygen species (ROS) and reactive nitrogen species (RNS) to a specific site. The heterogeneous composition of CAP offers the opportunity to mediate several signaling pathways that regulate tumor cells. Consequently, the array of CAP generated products has limited the identification of the mechanisms of action on tumor cells.

Characterization of an atmospheric pressure plasma jet and its applications for disinfection and cancer treatment.

In this work an atmospheric pressure non-thermal resistive barrier (RB) plasma jet was constructed, characterized and was applied for biomedical applications. The RB plasma source can operate in both DC (battery) as well as in standard 60/50 Hz low frequency AC excitation, and it functions effectively in both direct and indirect plasma exposure configurations. The characteristics of the RB plasma jet such as electrical properties, plasma gas temperature and nitric oxides concentration were determined using voltage-current characterization, optical emission spectroscopy and gas analyzer diagnostic techniques.

Regulated cellular exposure to non-thermal plasma allows preferentially directed apoptosis in acute monocytic leukemia cells.

This research investigated the modulation of cell death through exposure of non-thermal resistive barrier based indirect air plasma on monocytic leukemia cancer cells (THP-1). Specifically, we explored cell death through apoptosis and necrosis, since generally apoptotic cell death has a limited inflammatory response as compared to necrosis. We have demonstrated a preference for apoptosis in plasma treated THP-1 cells, under specific plasma characteristics and dosage levels, using fluorescent dyes conjugated with annexin V followed by identification of the cells through fluorescent microscopy and flowcytometry diagnostics.

Portable plasma medical device for infection treatment.

The purpose of this study was to determine the effects of plasma treatment on bacteria in liquid phases. We predict that the plasma gas can penetrate the liquid culture media and plasma treatment will efficiently kill the bacteria at unique time and distance parameters. It is also hypothesized that less stringent plasma treatment will negatively affect the growth rate of some species of bacteria and possibly their pathogenicity.

THP-1 leukemia cancer treatment using a portable plasma device.

This research study examined the effect of non-thermal portable atmospheric air plasma system on leukemia cancer cells. Acute monocytic leukemia cells (THP-1) were exposed to atmospheric pressure non-thermal plasma. To assess death caused by plasma exposure, cells were subjected to trypan blue exclusion assays and a kill-curve and assessment of death overtime were compiled using data from the assays.